Bone fixation plate

ABSTRACT

An apparatus for reducing the profile of a bone fixation plate while preventing backing out of screws is disclosed. The plate has at least two openings though which two screws can pass through bony tissue. The apparatus includes at least one section of relief and sections of engagement. As the screw is tightened, it will begin to lag the plate to the bone. When the screw head interferes with the plate at the interference point, there is a slight resistance that insertion forces can overcome. When the screw is advanced further, it snaps into the sliding fit area and is allowed to move freely. The forces that cause the screw to back out from the plate are preferably not strong enough to pass the screw head back past the interference section. At least one of the two openings is configured as an elongated slot to allow the screw to translate in the slot. It may be desirable to include a set screw to help prevent backout.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation application of U.S. patent application Ser. No. 13/543,447, filed Jul. 6, 2012, which is a continuation application of U.S. patent application Ser. No. 11/097,340, filed on Apr. 4, 2005, now issued as U.S. Pat. No. 8,236,034, which is continuation-in-part application of U.S. patent application Ser. No. 10/826,285, filed Apr. 19, 2004, now issued as U.S. Pat. No. 7,963,981, the entire contents of which are incorporated by reference.

FIELD OF THE INVENTION

The present invention relates to a bone fixation plate used to stabilize vertebrae and other bony anatomy. More specifically, the present invention relates to a cervical plate having a minimized profile that easily and reliably prevents backout of fastening devices.

BACKGROUND OF THE INVENTION

Bones and bony structures are susceptible to a variety of weaknesses that can affect their ability to provide support and structure. Weaknesses in bony structures may have many causes, including degenerative diseases, tumors, fractures, and dislocations. Advances in medicine and engineering have provided doctors with a plurality of devices and techniques for alleviating or curing these weaknesses.

The cervical spine has presented the most challenges for doctors, partially due to the small size of the vertebrae and the spacing between adjacent vertebrae. Typically, weaknesses in the cervical spine are corrected by using devices that fuse one or more vertebrae together. Common devices involve plate systems that align and maintain adjacent cervical vertebrae in a desired position, with a desired spacing.

These devices, commonly referred to as bone fixation plating systems, typically include one or more plates and screws for aligning and holding vertebrae in a fixed position with respect to one another. Initial devices used stainless steel plates and screws. In order to remain fixed in place, the screws were required to pass completely through the vertebrae and into the spinal canal. These devices caused many complications and involved significant risks. To allow a screw to pass, drilling and then tapping of the vertebrae was required. In the process, instruments came within close proximity of the spinal cord, which required extreme care on the part of the surgeon.

In addition to the risks of surgically applying bone fixation plates, other complications arose. Commonly, these problems involve loosening and failure of the hardware. Two common failures are the breakage of the plates, and the backing out of the screws into soft tissues of the patient's body. The backing out of the screws is typically a result of the screw's failure to achieve a sufficient purchase in the bone, although the stripping of the screws has also been known to cause this problem. Regardless of the cause of the hardware failures, a surgeon must repair or replace the broken parts, which requires undesirable invasive procedures.

Advances in material science allowed engineers to manufacture bone fixation plates out of materials that would resist breakdown within a body. However, the backing out of screws remained a problem. Many solutions were devised in an attempt to prevent this from occurring. One prevalent solution involved minimizing the length of the screw in order to prevent screw to plate junction breakage of the screw. However, the shortened screw is typically unable to achieve a sufficient purchase in the bone. Shortened screws often provide very little holding power and inadequate tactile feedback to the surgeon. Tactile feedback to the surgeon is important to signal completion of tightening prior to stripping of the screw within the bone.

An alternate solution involves increasing the length of the screws in order to achieve sufficient purchase to hold the plate in place. While the use of longer screws can provide bicortical fixation, this method also has its drawbacks. Primarily, long screws increase the chances of interference with each other when they are screwed into bony tissue at an angle. In addition, many bone fixation plating systems place bone grafts between vertebrae. The bone grafts are eventually supposed to spur the growth of bone between the vertebrae, so that the vertebrae become fused together naturally.

In order for this to occur, the bone fixation plating needs to maintain a desired spacing between the vertebrae, which is filled by the bone grafts. However, it is common for the bone grafts to experience compression, which separates at least one of the adjacent vertebrae from the bone graft. Cervical plates that employ long screws do not allow for sufficient movement of the vertebrae to accommodate the compression of the bone graft, because the purchase of the screws is too great. Thus, the vertebrae cannot move and are unable to adjusting to the compression of the bone graft.

Another method of preventing the backing out of screws involves placing a second plate over the screws. This second plate functions to interlock the screws, preventing them from backing out. However, this method of securing screws often becomes bulky, resulting in a large and undesirable profile. In addition, these configurations require carrying out multiple steps or using a multi-piece assembly in order to block an opening through which a loose fastener head may pass. For instance, the use of a c-ring that can expand as the fastener head is inserted requires additional components and assembly time to form a plate. Moreover, multi-component designs may lose their ability to retain a fastener over time due to material failure, relaxation, or the like. Additionally, multi-component configurations may not provide sufficient ability to lag the plate to the vertebral body.

One additional drawback of many designs is that they add to the overall height of the plate. It is desirable to maintain a low profile design for many reasons, such as to minimize irritation to surrounding tissue. For example a plate design having a high overall height or a receptacle design that does not prevent screw backout may cause a patient to suffer from dysphasia. Ultimately, the screw or plate may irritate or wear through neighboring tissue. In addition, a high height plate or unretained loose screw in the lumbar spine may be abrasive to the aorta or vena cava. Severe abrasion by the plate or screw in this instance may puncture the aorta or vena cava and cause internal bleeding.

In addition, many of these plates were not designed to allow for the locking of all of the screws, which left some of the screws susceptible to backout caused by tiny vibrations, or micromotion. Some methods attempted to reduce the profile of the total system by using small parts. However, this led to the small parts falling off and getting lost. In addition, the smaller parts are fragile and require special instruments in order to insert or manipulate them. In addition, because of their small size, incorrect placement relative to the axis of the plate often causes sharp and jagged shavings to be formed as a locking screw contacts an improperly seated bone screw.

Prior attempts at increasing the screw purchase have resulted in risky procedures, or an insufficient ability to adapt to movement. Attempts and decreasing the profile of bone fixation plates have resulted in lost parts, or insufficient purchase. A continuing need exists for an apparatus that is able to quickly and reliably lock a plurality of screws into place while maintaining a low profile.

SUMMARY OF THE INVENTION

The present invention relates to an apparatus for connecting a plate to a bone. This may be desirable in order to immobilize, for example, two cervical vertebrae. In one embodiment, the present invention comprises at least one screw and a plate having at least one opening. As the screw passes through the opening and is tightened, it begins to lag the plate to the bone. When the screw head interferes with the pate at an interference point, there is a slight resistance force that insertion forces can easily overcome. When the screw is advanced further, it snaps into the sliding fit area and is allowed to move freely. Forces which can cause the screw to back out of from the plate are preferably not strong enough to pass the screw head past the interference section. In some embodiments, it may be desirable to use a set screw to aid in preventing backout. Alternately, a clamp applied to the head of the screw to prevent rotation may be desired.

In one embodiment, the present invention comprises an apparatus for fixing a plate to bony material, comprising at least one opening having a spherical curvature. Also included is at least one fastener having a head that interferes with the spherical curvature at an interference point. In this embodiment, the head is capable of engaging with and passing the interference point to communicate with the spherical curvature.

In some embodiments, the spherical curvature includes at least one engagement area and at least one relief area. The tangents to the spherical curvature preferably intersect to form an angle. Preferably, the angle of intersection of the tangents is between about 1 and about 5 degrees. More preferably, the angle of intersection of the tangents is between about 1 and about 3 degrees.

It is desirable to limit the relief areas in some embodiments to prevent a screw from passing through the interference point. Accordingly, it is preferred that the relief area comprises less than about 40% of the circumference of the spherical curvature. More preferably, the relief area comprises less than about 30% of the circumference of the spherical curvature. In some embodiments, it may be desirable to provide an additional opening that is configured and dimensioned to increase the magnitude of interference at the interference point.

In another embodiment, the present invention comprises an apparatus for stabilizing at least two bony structures, comprising a plate where more than one aperture is configured and adapted to include an interference area. The interference area is integrally formed in the plate to prevent a fastener from backing out of the interference area.

In this embodiment, a fastener, such as a screw, is capable of engaging with and passing through the interference area. The interference area is part of spherical curvature, which has at least one engagement area and at least one relief area.

Preferably, the tangents to the spherical curvature intersect. It is desirable to have the angle of intersection of the tangents between about 1 and 5 degrees. In some embodiments, it is also preferable to include another opening that is selectively positioned to increase the magnitude of interference at the interference point. The opening may be configured and adapted such that it is able to pass a wedge shaped screw.

In another embodiment, the present invention comprises an apparatus for fixing a plate to bony material consisting essentially of at least one opening having a spherical curvature. At least one fastener having a head capable of engaging with and passing through an interference point of the spherical curvature is also included. In this embodiment, the fastener is prevented from backing out of the opening by the interference point. In this embodiment, the tangents to the spherical curvature intersect. As described above, another opening may be selectively positioned to increase the magnitude of interference at the interference point.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will become more fully understood from the detailed description and the accompanying drawings, wherein:

FIG. 1 is a diagram showing one embodiment of the bone fixation plate according to the present invention;

FIG. 2 is a diagram showing a side view of exemplary openings according to the present invention;

FIG. 3A is a diagram showing one embodiment of the spring loaded plate according to the present invention;

FIG. 3B is a diagram showing an exemplary ramped surface included in the spring loaded plate of FIG. 3A;

FIGS. 4A and 4B are diagrams showing an exemplary embodiment of a set screw according to the present invention;

FIGS. 5A and 5B are diagrams showing an exemplary embodiment of a bone screw according to the present invention;

FIG. 6 is a diagram showing another embodiment of the bone fixation plate according to the present invention;

FIG. 7 is a diagram showing one embodiment of the spherical curvature according to the present invention;

FIG. 8 is a diagram showing the forces exerted by the screws according to the embodiment shown in FIG. 6;

FIG. 9 is a diagram showing another embodiment of the bone fixation plate according to the present invention;

FIGS. 10A and 10B are illustrations of additional embodiments of bone fixation plates of the present invention;

FIG. 11 is a diagram showing a one embodiment of the bone fixation plate according to the present invention;

FIG. 12 is a diagram showing a drill guide in communication with a bone fixation plate of the present invention;

FIG. 13 is a magnified view of a drill guide in communication with a bone fixation plate of the present invention;

FIG. 14 is a side view of a drill guide in communication with a bone fixation plate of the present invention;

FIGS. 15A-C are diagrams showing an exemplary embodiment of a rigid bone screw according to the present invention;

FIG. 16 is an illustration of one embodiment of a drill guide capable of rotating about an axis of a receptacle or depression formed in the plate;

FIG. 17 is a diagram showing one embodiment of the bone fixation plate according to the present invention;

FIG. 18 is a diagram showing a side view of exemplary openings according to the present invention;

FIG. 19 is a diagram showing a side view of an elongated slot and the translational movement capable by a fastener;

FIG. 20 is an elevated view of another embodiment of a plate according to the present invention;

FIG. 21 is an elevated view of one example of one type of existing plate configuration;

FIG. 22 is an elevated view of another embodiment of a plate according to the present invention; and

FIG. 23 is an elevated view of another embodiment of a plate according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present invention relates to a bone fixation plate that minimizes the problems associated with prior bone fixation plates while maintaining a small profile. In one embodiment, as a screw is tightened, it will begin to lag the plate to the bone. When the screw head interferes with the plate at an interference point, a slight resistance is generated. The insertion forces can easily overcome this resistance. When the screw is advanced further, it snaps into a sliding fit area and is allowed to move freely. The forces which can cause the screw to back out from the plate are preferably not strong enough to pass the screw head back past the interference section. It may be desirable to include a set screw to prevent backout of the screws due to micromotion. In other embodiments, the head of the screw may be clamped to prevent rotation, when such a restriction on the movement of the screw is desirable.

The present invention provides a locking mechanism that allows one or more bone screws used for attaching a plate to vertebrae to be easily and reliably locked in place at the same time by a single operation. When fully installed, the locking mechanism has a low profile and maintains its ability to prevent breakout of screws due to micromotion. The present invention may be used on the anterior or posterior of the vertebrae. Although the present invention is described with respect to two bone fixation vertebrae, it will be understood that the following embodiments are capable of being used with any number of vertebra, in any spinal location.

Turning now to the drawings, FIG. 1 shows one embodiment of a bone fixation plate 101 according to the present invention. The plate may be secured to two vertebrae in order to maintain the vertebrae integrally with respect to one another in a desired orientation and at a desired spacing from one another. Plate 101 includes two fastening devices, such as screws 103, 105 or the like, which are operatively communicable with spring loaded plates 107, 109. The plate also includes four openings 111, 113, 115, and 117, through which screws (not shown) may be used to fasten the plate 101 to the vertebrae.

The plate 101 and the screws may be comprised of any material, such as a metal, alloy, or any combination of the two. Preferably, the material used to construct the plate and the screws allows the plate 101 to maintain its structural integrity while allowing for a desired amount of resiliency. Furthermore, the material used is preferably bio-compatible and capable of withstanding the conditions of a body over a desired period of time. In some embodiments, this is achieved by manufacturing the plate 101 and screws using metals such as titanium or stainless steel. Titanium has sufficient ductility to permit a desired amount of curving of the plate 101 to conform to the shape of the vertebrae, yet has the strength to maintain its structural integrity.

In the FIG. 1 embodiment, the bone fixation plate 101 comprises a center portion 119 and two distal portions 121, 123. Each distal portion 121, 123 may be attached to a different vertebra using fasteners, such as screws, that pass through openings 111, 113, 115, and 117. Because distal portions 121, 123 are similar, only the operation of distal portion 121 is described in detail.

FIG. 2 is a diagram showing a side view of openings 111 and 113. In one embodiment, each opening has a substantially circular shape, as shown in FIG. 1. In this embodiment, the inner portion of openings 111, 113 have substantially spherical curvatures. Accordingly, the radius of the inner portion of openings 111, 113 decrease in diameter from the top 201 of the openings, to the bottom 203 of the openings. Preferably, the spherical curvature of the openings 111, 113 may accommodate a screw having a spherical head. However, the present invention is not limited to spherical curvatures or spherical heads. In other embodiments, any complementary head and receptacle may be used. Preferably, the complementary head and receptacle are capable of preventing the breakout of the screw.

As shown in FIG. 2, the openings 111, 113 are not continuous. It is desirable that the openings 111, 113 comprise only a portion of the circumference of the spherical curvature. In one embodiment, the remaining portion 205 of the circumference of the spherical curvature of the openings 111, 113 is provided by spring loaded plate 107, shown in FIG. 1. The portion of the circumference of the spherical curvature that is completed by spring loaded plate 107 may be varied as desired, for example, according to the amount of resistance that is desired by the spring loaded plate 107. In one embodiment, the openings 111, 113 comprise at least 60 percent or more of the total circumference of the spherical curvature. In another embodiment, the openings 111, 113 comprise at least 70 percent or more of the total circumference of the spherical curvature. In yet another embodiment, the openings 111, 113 comprise at least 80 percent or more of the total circumference of the spherical curvature.

FIG. 3A is a diagram showing one embodiment of the spring loaded plate 107. In this embodiment, the spring loaded plate 107 includes arm 301. When a force causes arm 301 to be deflected towards the body 303 of the spring loaded plate 107, potential energy is stored in the arm 301. This potential energy causes the arm 301 to generate spring-like forces that have a tendency to force it away from the body 303, and back to its natural resting position shown in FIG. 3A. When the deflection force is removed, the potential energy is converted to kinetic energy, and forces the body 303 away from the arm 301. In other embodiments, the spring loaded plate 107 does not have to have a free cantilever load such as the arm 301 shown in FIG. 3A. For example, it may be desirable to use a loop, or the like, to resist movement of the spring loaded plate 107.

The inner portion of plate 107 preferably comprises a ramped surface 305. In one embodiment, the ramped surface 305 is selectively engageable with screw 103, shown in FIG. 1. When the screw 103, is engaged by the ramped surface shown in FIG. 3B, outward forces are generated on the screw, preventing it from backing out. As the angle of the ramped surface increases, the forces that are exerted on the screw 103 increase. Thus, the angle of the ramped surface may be chosen based on the amount of force that is desired to keep the screw 103 from backing out.

In one embodiment, the angle of the ramp is between about 5 and 50 degrees. In another embodiment, the angle of the ramp is between about 10 and about 30 degrees. In yet another embodiment, the angle of the ramp is between about 15 and 25 degrees.

The spring loaded plate 107 comprises two spherical curvatures 307 and 309. Spherical curvatures 307 and 309 complete the spherical curvatures of openings 111 and 113. Each curvature 307, 309 comprises a spherical curvature having a radius that decreases from top to bottom, as discussed with respect to the curvatures of openings 111 and 113. The spherical curvatures 307, 309 may comprise any desired percentage of the circumference of the total spherical curvature. In one embodiment, each curvature 307, 309 may comprise 20 percent or less of the total circumference of the spherical curvature. In another embodiment, each curvature 307, 309 may comprise 30 percent or less of the total circumference of the spherical curvature. In yet another embodiment, each curvature 307, 309 may comprise 40 percent or less of the total circumference of the spherical curvature.

Spring loaded plate 107 also includes two edges 311 and 313, shown in FIG. 3A. Each edge is preferably configured and dimensioned to be engageable with a depression 125 in plate 101. In one embodiment, the spring loaded plate 107 is positioned within the depression 125. Depression 125 is configured and dimensioned such that there is sufficient space for plate 107 to move between its compressed and relaxed states, described with respect to FIGS. 3A and 3B. In one embodiment, plate 107 is prevented from horizontally exiting depression 125 by the protrusion formed by openings 111, 113.

In one embodiment, shown in FIGS. 4A and 4B, the screw 103 may have an angled head 401. It may be desirable for screw 103 to have threads along its elongate shaft 403. In order to aid in tightening screw 103, it preferably includes a projection 405 with a curved surface to aid in gripping the screw. The length of the elongate shaft may be varied as desired. In one embodiment, the length of the elongate shaft is about 5 mm or less. In another embodiment, the length of the elongate shaft is about 3 mm or less. In yet another embodiment, the length of the elongate shaft is about 1 mm or less.

FIGS. 5A and 5B are diagrams showing one embodiment of the screw that is used to connect plate 101 to vertebrae. Screw 501 preferably has a spherical head 503 that is selectively engageable with the spherical curvature. An elongate shaft 505 is connected to the spherical head 503 to allow it to penetrate bony tissue of the vertebrae. Preferably, the elongate shaft 505 includes threads that aid in fixing the plate 101 to a vertebra. As shown in FIG. 5B, it is desirable to have a hexagonal projection 507 to aid in gripping the screw.

The length of the elongate shaft 505 may be varied as desired. In one embodiment, the length of the elongate shaft is about 20 mm or less. In another embodiment, the length of the elongate shaft is about 10 mm or less. In yet another embodiment, the length of the elongate shaft is about 5 mm or less.

In one embodiment, screw 103 is inserted into a receptacle in depression 125. It is desirable to have a threaded receptacle such that the screw is capable of being fixed to the plate 101. The screw 103 also passes over plate 107, and prevents it from vertically exiting depression 125. The placement of the screw receptacle is preferably chosen such that it is engageable with the ramped surface 305 of plate 107 when the plate is in its relaxed state, with its arm 301 extended.

Preferably, two screws 501 are inserted into openings 111 and 113. As the screws 501 are tightened, they will begin to lag the plate 101 to the bone. When the screw head 503 interferes with plate 107, it forces it to move towards the center of the plate 101. As the screws 501 are advanced further, the plate 107 forces its way back into its relaxed state. This causes the spherical curvatures 307, 309 to form a complete spherical curvature around the screw head 503. When plate 107 is in its relaxed state, it prevents screw 501 from backing out. It may be desirable to tighten screw 103, such that plate 107 remains fixed in its relaxed state. In this manner, the screw 501 is prevented from backing out.

Screws 501 may be screwed into bony tissue at any desired angle. In other words, screw 501 does not have to be inserted perpendicular to the plate 101. The spherical properties of the head of the screw 503 and the spherical curvature of the openings 111, 117 are preferably sufficient to prevent the screw from backing out. Thus, the largest diameter of the head of the screw is larger than the diameter of the narrowest portion of the opening in the top outer side of the plate through which the screw head is placed. The interference difference between the fastener head diameter and the outer narrow opening may be describe in different ways depending on the size of the plate, openings, and fastener heads being used. For example the interference difference between the fastener head and the narrowest opening may be about 0.01 mm or greater, about 0.03 mm or greater, or about 0.10 or greater, or even about 0.20 mm or greater. Preferably, however, in each instance the interference is less than about 2 mm.

Alternatively, the interference between the fastener head and the narrow outer opening may be described relative to the outer diameter of the fastener head itself. For example, the interference may be about 0.5% or greater of the diameter of the fastener head, about 5% or greater of the diameter of the fastener head, or even about 10% or greater of the outer diameter of the fastener head. Preferably, however, in each instance the interference is less than about 40% of the outer diameter of the fastener head.

While openings 111, 117 prevent the screws 501 from backing out, they do allow it to rotate freely within the spherical curvature. One advantage of allowing the screw 501 to rotate freely is that the bone fixation plate according to the present invention is able to accommodate for movements in the vertebrae or accommodate for compression of the bone grafts that are placed between vertebrae. Another advantage of allowing the screws to be inserted at any angle is that it allows relatively close spacing of the screws, without the risk of interference with one another.

FIG. 6 shows another embodiment of the present invention. As shown in FIG. 6, an exemplary bone fixation plate according to the present invention comprises four openings 601, 603, 605, and 607. In one embodiment, openings 601, 603 are connected to one vertebra, and openings 605, 607 are connected to a second vertebra. Also included are two additional openings 609, 611, which are located at a desired point between points 601, 603 and 605, 607, respectively. One advantage of the FIG. 6 embodiment is that a screw does not have to be inserted into opening 609 until after screws are inserted into openings 601, 603. Thus, opening 609 serves as a window for a surgeon to view the vertebra, or space between adjacent vertebrae. This is often desirable to the surgeon.

Because all of the corresponding openings are similar, only openings 601, 603 and 609 are described in detail. In one embodiment, openings 601 and 603 are spherical curvatures having the same properties discussed with respect to FIGS. 1-5. Thus, a complete description of the openings 601, 603 is not repeated. The openings are substantially similar in size, shape, and diameter to the openings 111, 113, 115, and 117 described with respect to FIG. 1. There are some differences between the openings shown in FIG. 6 embodiment and the openings shown in the FIG. 1 embodiment, which are discussed below.

In one embodiment, the spherical curvature of openings 601, 603 is substantially circular. The opening 601, 603 comprises the majority of the circumference of the spherical curvature for the screw 613. This is in contrast to the spherical curvatures described with reference to FIGS. 1-5, which were formed by both the openings and the spring loaded plate 107. Therefore, the spherical curvature of each opening 601, 603 houses substantially the entire head of screw 613. In one embodiment, screw 613 is substantially similar to screw 501, discussed with reference to FIGS. 5A and 5B.

In one embodiment, the spherical curvature of the opening 601, 603 comprises 90% or more of the total circumference of the curvature. In another embodiment, the spherical curvature of the opening 601, 603 comprises 95% or more of the total circumference of the curvature. In yet another embodiment, the spherical curvature of the opening 601, 603 comprises 99% or more of the total circumference of the curvature.

In one embodiment, opening 609 is selectively positioned between openings 601, 603. Opening 609 preferably allows a screw 615 to pass, which increases the interference between the spherical curvature of the opening 601, 603 and the head of the screw 613. As shown in FIG. 6, the placement of the openings 609, 611 may be varied. In one embodiment, the opening may be positioned such that it is positioned directly in between the openings or slightly higher than the openings. However, in another embodiment the opening 609, 611 may be placed at a desired distance above the openings.

In order to use screw 615 to tighten the openings 601, 603 around the head of screw 613, openings 601, 603 comprise a fixed portion and a flexible portion 617. In one embodiment, flexible portion 617 is formed by a discontinuity that is formed in openings 601, 603 and opening 609. When the flexible portion 617 of the opening is pushed against the screw 615, increased interference results. One advantage of the increased interference is that backout of the screw 615 is prevented.

The discontinuity 619 should be large enough that it allows flexure of portion 617 of the spherical curvature, while allowing the spherical curvature to maintain its structural integrity and provide a sufficient contact area for the head of the screw 613. In one embodiment, the discontinuity 619 shown in FIG. 6 comprises a small portion of the total circumference of the opening 601, 603. The discontinuity 619 may be vertical, or it may be configured and dimensioned at a desired angle.

In one embodiment, the discontinuity 619 comprises about 5% or less of the total circumference of the curvature. In another embodiment, the discontinuity comprises about 3% of less of the total circumference of the curvature. In yet another embodiment, the discontinuity comprises about 1% or less of the total circumference of the curvature.

In the FIG. 6 embodiment, tangents to the curvature of opposing points along the spherical curvature intersect. This is in contrast to typical cylindrical curvatures that have been used for bone fixation plates, where the tangents to the curvature of opposing points do not intersect. One advantage of having the tangents to the curvature intersect is that the spherical curvature generates an interference area. As the head of the screw being screwed into place, a sufficient amount of force may be applied to force the head of the screw to contract slightly. As the screw continues into the bone, the head of the screw is able to pass through the interference area. Once the head of the screw passes through the interference area it fits into the spherical curvature. It is desirable that forces that force the screw to backout are not strong enough to force the screw back through the interference area. This resistance of the interference area may be modified by changing its curvature.

In one embodiment, tangents to spherical curvature intersect to form an angle, as shown in FIG. 7. This angle is preferably between about 1 and about 10 degrees. In another embodiment, the angle between the tangents is between about 1 and about 5 degrees. In yet another embodiment, the angle between the tangents is between about 1 and about 3 degrees.

In one embodiment, opening 609 is substantially similar to openings 601, 603. That is, it has a substantially spherical curvature. In other embodiments, however, opening 609 may not have a substantially spherical curvature. The curvature may be shaped to receive a screw 615 having a flat head. However, other types of screws may be used. In embodiments where screw 615 has threads, the receptacle may be configured to receive the threads in order to prevent screw 615 from backing out. To allow an instrument to grip the screw, a hexagonal depression may be configured on the head of the screw. However, in other embodiments it may be desirable to have a curved protrusion to aid in gripping the screw 615.

The diameter of opening 609 is preferably smaller than the diameter of openings 601, 603. The diameter of opening 609 may be smaller than the diameter of openings 601, 603 because the screw 615 that passes through the opening does not have to pass through bony tissue. In one embodiment, opening 609 and screw 615 function to further restrict openings 601, 603 after the screw 613 has been inserted.

Screw 615 may be screwed into bony tissue at any desired angle. In other words, screw 615 does not have to be inserted perpendicular to the plate. The spherical properties of the head of the screw 615 and the spherical curvature of the openings 601, 603 are preferably sufficient to prevent the screw from backing out. While openings 601, 603 prevent screw 613 from backing out, they do allow it to rotate freely. One advantage of allowing the screw 613 to rotate freely is that the bone fixation plate according to the present invention is able to accommodate movements in the vertebrae or accommodate for compression of bone grafts that may be placed between vertebrae. Another advantage of allowing the screws to be inserted at any angle is that it allows relatively close spacing of the screws, without the risk of interference with one another.

As described above, openings 609, 611 may be placed in any desired position. In some embodiments, it may be desirable to position the opening 611 directly in line with openings 605, 607. However, in other embodiments it may be desirable to place the opening 609 at a higher position than the openings 601, 603. FIG. 8 is a diagram showing exemplary forces that may be exerted on the openings 601, 603, 605, and 607 when screws are inserted into openings 609 and 611.

As shown in FIG. 8, when the opening 609 is positioned at a higher position than openings 601, 603, the screw exerts forces on parts of the openings 601, 603. Because the magnitude of interference between the openings 601, 603 and the screw 613 is not as great, this embodiment may be preferable in applications where a significant amount of movement or shifting of the vertebrae is expected. The lower magnitude of interference allows the screws to shift to accommodate these movements. However, when the opening is positioned directly in line with openings 605, 607, the screw exerts forces on a larger portion of the openings 605, 607. Because of the increased magnitude of interference between the openings 605, 607 and the screw 613, this embodiment may be desirable when it is preferable to have the plate held in place with more force.

FIG. 9 is a diagram showing another embodiment of the present invention. In this embodiment, the present invention comprises at least two openings through which screws may pass. The screws used in this embodiment are similar to the screws described with respect to FIGS. 1-8, thus a discussion of them is not repeated. In some embodiments, a third opening may be selectively positioned between the at least two openings in order to prevent a screw from backing out of the openings. Though only one set of openings is shown in FIG. 9, a corresponding set of openings are also attached to an adjacent vertebra. Adjacent sets of openings are preferably connected by two elongate shafts 909 and 911.

As shown in FIG. 9, openings 901, 903 comprise spherical curvatures, as described with reference to FIGS. 1-8. As described with reference to FIG. 7, tangents to the spherical curvature intersect to form an angle. The angles are similar to those discussed with reference to FIG. 7, and therefore are not repeated. In addition to the spherical curvature described with reference to FIG. 7, an embodiment in FIG. 10A includes alternating sections of engagement 905 and sections of relief 907. These sections of engagement 905 and relief 907 are preferably located along the top portion of the spherical curvatures, from which the screw is inserted. One advantage of having one or more sections of engagement and relief is that the opening 901 is able to accommodate micromotion of the screw, or in some cases, of the entire plate.

In one embodiment, the openings 901, 903 comprise a single relief section. This provides the advantage of allowing a screw to adjust due to micromotion, while preventing the screw from backing out. In this embodiment, the remainder of the openings 901, 903 is a section of engagement. The section of engagement preferably resists the motion of the screw.

In another embodiment, more than one section of relief 907 may be included. More than one relief section 907 may be desirable in embodiments where micromotion may be prevalent. The sections of relief 907 allow the angle of the screws to vary while preventing it from backing out. However, it is undesirable to include too many sections of relief 907. It is desirable to have more sections of engagement 905 than sections of relief 907 because too many sections of relief will result in the magnitude of the interference point being reduced at different angles. Thus, in a preferred embodiment, the openings 901 and 903 include more sections of engagement 905 than sections of relief 907.

In one embodiment, the number of relief sections 907 included in the openings is two or greater. In another embodiment, the number of relief sections that are included in the openings is four or greater. In yet another embodiment, the number of relief sections that are included in the openings is six or greater.

In some embodiments, the portions of the opening that are relief sections 907 and the portion of the openings that are engagement sections 905 may be expressed as a percentage of the total circumference of the openings 901, 903. Preferably, the sections of relief comprise about 50% or less of the circumference of the openings. More preferably, the sections of relief comprise about 40% or less, and most preferably the sections of relief comprise about 30% or less of the circumference of the openings. 10871 In one embodiment, a third opening 913 may be placed between openings 901, 903. A set screw may be placed in opening 913 and increase the interference of the openings 901, 903 against the head of the screw. In order to allow the screw to increase the interference between the openings 901, 903 and the screw, a wedge shaped depression 915 may be configured and dimensioned in the plate. The FIG. 9 embodiment provides the advantage of minimizing the profile of the bone fixation plate while increasing its ability to accommodate for micromotion.

In this embodiment, as a screw is tightened, it will begin to lag the plate to the bone. When the screw head interferes with the spherical curvature at an interference point, a small amount of resistance is generated. The interference, and resulting resistance, are caused by the angle of intersection of the tangents to the spherical curvature. As described above, the spherical curvature has tangents that intersect. The interference forces are easily overcome by the screw head. When the screw advances further, it snaps into the spherical curvature and is allowed to move freely. The forces which cause the screw to back out from the plate are preferably not strong enough to pass the screw head back past the interference section. To further assure that the screw head does not pass back past the interference section, the set screw described above may be employed.

Referring now to FIGS. 11-14, the plate of the present invention may be configured to aid in the insertion of bone screws. For example, FIG. 11 illustrates that the plate may have one or more openings 1101 that are capable of securely receiving a drill guide. For example, the openings may be configured with threads that engage with a threaded tip of the drill guide. In addition, the plate may also have one or more recesses, pivot points, depth stops, or areas of removed material in the top surface of the plate that help align the drill guide opening over the holes of the plate. The drill guide may have a rotating barrel that rotates along an axis that extends through the recess of the plate. In one embodiment, a portion of the drill guide can be aligned with and contact the recess while providing a base on which the barrel can rotate. Alternatively, as shown in FIG. 16, a portion of the barrel itself may reside in the recess of the plate upon which the drill guide may be rotatably disposed.

As shown in FIG. 13, the barrel may have a drill bore extending through its length. When the drill guide is properly aligned with the recess and opening, the barrel may be rotated to a first position such that the drill bore is aligned over a hole in the plate where a bone fastener will be placed. Preferably, the bore is configured so that its axis passes through the spherical opening in the plate. The portion of bone beneath the plate may then either be prepared for receiving a fastener by drilling a pilot hole in the bone, or alternatively a fastener may be placed directly into bone. To further ensure that the fastener is inserted at a proper angle, it may be inserted through the bore.

Once a first fastener has been inserted into a first hole of the plate, the barrel may be rotated such that it is aligned over a second hole in the plate, thereby allowing a second fastener to be inserted without having to reposition the entire drill guide. As shown in FIGS. 11-14, a plurality of guide holes and recesses may be provided in the plate. In one embodiment, one recess and guide hole may be used to insert fasteners into two bone screw holes.

As discussed above, once a fastener head has passed the interference area it may freely swivel or rotate to accommodate different angles or to allow for reabsorption of graft material over time. As graft material or bone is reabsorbed by the body, loading previously borne by the bone may be transferred instead to the plate. Thus, it may be preferable in some circumstances to have one or more fastener, preferably two or more fasteners, remain substantially free to swivel or rotate to account for dimensional changes in the bone that may occur after insertion of the plate.

In some cases, however, it may be desirable to rigidly fix the angle of the fastener relative to the plate once it is deployed. While some devices have been developed in the past to help resist or prevent micromovement of a plate relative to a fastener or to the bone that the plate contacts, past designs have either lacked the ability to be inserted at varying angles or have required complex designs or additional components in order to achieve multi-angel variability.

One example is described in U.S. Pat. No. 4,484,570, which is incorporated herein in its entirety. In particular, this reference discusses that reabsorption of the bone may take place at a portion of the contact surface between the bone and the plate. Over time, this reabsorption can cause open gaps to be formed, which may eventually become large enough that varying loads acting on the bone can cause undesirable micromovement between the plate, bone, and fasteners. This reference addresses this issue by describing a fastener having a head configured with a generally conical outer surface and having one or more slots. The fastener head further has a clearance hole or receptacle in which an expanding set screw may be inserted to splay or direct portions of the slotted head radially outwards. The interior surface of the fastener head is also generally conical and corresponds to a conical outer surface of the set screw. Thus, as the set screw is driven further into the clearance hole or receptacle, the interaction between the two conical surfaces applies progressively greater amounts of locking force. As mentioned above, one disadvantage to the locking fastener system described in the '570 patent is that it is not capable of permitting adjustability of the fastener with respect to the plate.

Another example is found in U.S. Pat. No. 6,235,033, which also is incorporated herein in its entirety. In particular, the '033 patent purports to achieve multi-angle variability of a plate design based substantially upon the addition of a c-ring to the design described in the '570 patent. In particular, the '033 patent likewise teaches to use a fastener having a slotted head with a generally conical outer surface. The conical surface of the fastener can be connected to a c-ring that resides in the opening of the plate through which the fastener is inserted. The outer surface of the c-ring slidingly engages with the spherical surface of the hole in the plate to provide variation in the angle of the fastener. When desired, an expansion screw may be deployed in a receptacle formed in the fastener head so that the outer surface of the fastener head applies outward pressure against the c-ring. Eventually, the c-ring expands sufficiently to apply pressure against the opening in the plate that locks the fastener relative to the plate. One disadvantage to this multi-angle locking system, however, is that it requires that the plate be assembled with a c-ring in each opening or hole through which a fastener will be placed.

While any of the various methods and techniques described in these references for having the fastener head capable of applying an outward force may be used, the present invention also relates to an improved way to achieve multi-angle variability while preserving simplicity of design. Rather than using a complex, multi-piece plate construction or sacrificing the ability of the fastener to have variable angles relative to the plate, the present invention contemplates forming the outer surface of a slotted fastener head to have a curved or spherical shape corresponding generally to the curvature of a portion of the plate holes in which the fastener will be placed. Thus, the fastener may be inserted into a plate hole at a variety of angles and be selectively locked in position without the use of a c-ring, bushing, or the like to aid in providing multi-angle variability. Once the fastener is in its desired position, a set screw may be inserted into a receptacle in the fastener head to rigidly hold the fastener in a fixed position relative to the plate.

The outer surface of the curved fastener head may be textured to provide increased locking forces. For example, a portion of the outer surface of the fastener head may be configured with circular grooves that help hold the fastener in place as the slotted head is expanded outward against the inner surface of the plate hole. Likewise, the outer surface of the fastener may be roughened to provide increased resistance to slippage between the fastener head and the plate when in a rigid position.

FIGS. 15A-C illustrate one example of a fastener of the present invention that is capable of selectively providing the ability to swivel or move and to hold a fixed position. In particular, the fastener head has an outer surface that is generally spherical in shape, thereby allowing it to rotate or swivel once past the interference area. The fastener head also has a plurality of slots or cuts in the head that permit the head to expand or compress. The fastener head also may have an interior space that is capable of securely receiving a second fastener, such as a set screw, a cam, or the like. As the second fastener is inserted into this interior space, its causes the diameter of the first fastener head to increase and press against the inner wall of the bone screw opening in the plate, thereby locking it in place. As stated above, the outer surface of the first fastener head may be textured to further increase the ability to rigidly hold the fastener in place.

The inner space of the first fastener and outer shape of the second fastener may have different configurations to create and apply a locking force. For example, in one embodiment the set screw, interior space, or both may have a generally conical shape that progressively applies greater outward forces as the set screw or second fastener is inserted. Likewise, the interior space, second fastener head, or both may be generally cylindrical with the diameter of the second fastener being greater than the inner diameter of the interior space.

Thus, in accordance with the present invention, the bone fixation plates and components described with reference to FIGS. 1-15 may be secured to vertebrae and other bony material in a manner that prevents the screws from working loose when subject to vibration. Furthermore, the embodiments described above prevent the backing out of screws while minimizing the profile of the bone fixation plate. Retaining features, provided near each opening through which a screw may pass, is moveable between relaxed and flexed positions. Another advantage of the present invention is that screws that fasten the plate to the bony tissue may be oriented at a variety of non-perpendicular angles with respect to the plate, which allows a relatively close spacing of fasteners without the risk of fasteners interfering with one another.

In some instances increased translational movement of the plate relative to a fastener or to the bone that the plate contacts is preferred. By increasing the mobility of the plate after insertion, loading forces may be distributed between the plate and graft to diminish graft dislodgment and improve bone graft fusion rates. It has been found, for example, that by increasing the load force on the graft through controlled subsidence, bone graft fusion rates are increased. In addition, translational movement of the fastener within the plate can aid the surgeon during insertion of the plate. Also, increased translational movement of a plate protects the plate from fatigue because the plate maintains load sharing even in the presence of subsidence or bone resorbtion. Thus it may be preferable in some circumstances to have a plate that allows for constrained translational movement of the plate relative to a fastener or to the bone that the plate contacts.

While some devices have been developed in the past to help impart micromovement of a plate relative to a fastener or to the bone that the plate contacts, past designs have either lacked the advantage of constrained translational movement combined with the ability to insert fasteners at varying angles or have required complex designs or additional components in order to achieve constrained translational movement. For example, U.S. Pat. No. 6,695,846 (“the '846 patent”), which is incorporated herein in its entirety, discusses the use of apertures consisting of elongated slots that allow a screw to slide freely within the elongated slot. This reference discusses the use of a separate screw retaining mechanism that partially covers a portion of the screw. The screw retaining mechanism disclosed is a separate component of the cervical plate system and takes the form, in at least one example, of a circular metal disk. The reference discusses the retaining mechanism as a lockable component, meaning that the retaining mechanism may be in either a locked or unlocked position. One disadvantage of the retaining mechanism discussed in the '846 patent is that the system requires that the plate be assembled with a separate retaining mechanism that must be assembled during placement of the plate. Another disadvantage of the subject matter discussed in the '846 patent is that the holes for the plate do not allow rotational movement of the screw and do not provide for angular placement of the screws.

In one embodiment of the present invention, an improved plate that allows translational movement of the plate relative to a fastener or the bone that the plate contacts wherein the plate further comprises an interference area to prevent a fastener from backing out is provided. This simple, yet effective, design avoids using complex, multi-piece plate constructions.

FIG. 17 illustrates one embodiment of a plate 1700 according to the present invention that is capable of translational movement. In particular, the plate comprises a center portion 1702 and two distal portions 1704, 1706. Each distal portion 1704, 1706 may be attached to a different vertebra using fasteners, such as screws, that pass through openings 1708, 1710, 1712, 1714.

The interference area used to prevent a fastener from backing out has been described above. In the embodiment of FIGS. 17-19, plate 1700 includes at least one pair of the openings 1708, 1710 that are not substantially circular in shape, but rather, are elongated slots that allow for translational movement of the plate relative to a fastener or the bone that the plate contacts. In this regard, the elongated openings 1708, 1710 provide a surgeon with a substantial margin of adjustment and proper localization of a fastener. While the openings 1708, 1710 of the present embodiment are elongated slots, the inner portions have generally spherical curvatures in a cross-sectional side-view (as shown in FIG. 18) along lateral sides of the slots. Preferably there is at least one pair of elongated slots per plate, with the slots being positioned at one of the distal portions of the plate, allowing for controlled subsidence because of the translational motion of the plate-fastener interface. Alternatively, two pairs of elongated slots may be positioned at both distal portions of the plate.

As shown in FIG. 17, the slots have a generally elliptical like shape, with a major axis 1716 extending longitudinally and minor axis 1718 extending laterally transverse to the major axis 1716. Each of the openings 1708, 1710 is dimensioned such that it extends longitudinally a distance greater than the lateral width of the openings. The longitudinal length of the opening may be designed according to the amount of translational movement desired for any particular plate. The greater the length of the opening, the greater the amount of translational movement the plate will accommodate. The amount of translational movement a plate accommodates may be described in different ways depending on the size of the plate, openings, and fastener head being used. For example, a translational plate may be designed such that the length of the slot is 5 mm or greater, about 8 mm or greater or about 11 mm or greater, or even about 14 or greater. In one embodiment, however, the length of the elongated slot is less than about 20 mm. Alternatively, the length of the openings 1708, 1710 may be described as a percentage of the diameter of the fastener head. For example, a translational plate may be designed such that the length of the elongated slot is about 1.5 times or greater the outermost diameter of the fastener head being used, or about 2.0 times or greater, or even about 3.0 times or greater. In one embodiment, however, the length of the elongated slot is less than about 4.0 times or greater the outermost diameter of the fastener head being used.

The lateral width of each of the openings 1708, 1710 is dimensioned such that the upper lip 1802 of the substantially spherical curvature 1804 of the elongated slot interferes with the screw head 1902 to create an interference region along the lateral edges of the slot (see e.g. FIG. 10). When the screw head interferes with the spherical curvature, a small amount of resistance is generated. As described above, the spherical curvature has tangents that intersect. The interference, and resulting resistance, is caused by the angle of intersection of the tangents to the spherical curvature along the minor axis. The interference forces are easily overcome by the screw head. When the screw advances further, it snaps into the spherical curvature and is allowed to move freely. The forces which cause the screw to back out from the plate are preferably not strong enough to pass the screw head back past the interference section.

In this embodiment, the narrowest part of each opening 1708, 1710 is generally along or near the upper surface of plate 1700. The spherical properties of the head 1902 of the screw 1900 and the spherical curvature of the openings are preferably sufficient to prevent the screw from backing out. Thus, the largest diameter of the head 1902 of the screw 1900 is larger than the width of the narrowest portion of the opening in the top outer side of the plate through which the screw head is placed. The interference difference between the fastener head diameter and the outer narrow opening may be described in different ways depending on the size of the plate, openings, and fastener head being used. For example, the interference difference between the fastener head and the narrowest opening may be about 0.01 mm or greater, about 0.03 mm or greater, or about 0.10 or greater, or even about 0.2 mm or greater. Preferably, however, in each instance the interference is less than about 2 mm.

It is contemplated that the elongated slots of this embodiment will follow the curvature of the plate. Hence, the axis perpendicular to the elongated slot at any particular point will also be substantially perpendicular to the outer and or inner surfaces of the plate at any point along the major axis of the elongated opening.

It is further contemplated that the slot will allow the screw to translate within the opening after insertion. The interference area prevents the screw from backing out, and retains the screw within the slot. As seen in FIG. 19, the slotted opening, however, allows the screw to translate within the elongated slot. Once the screw has been placed, even though it is capable of translational movement within the slot, the spherical curvature along the major axis continues to provide an interference area to prevent the screw from backing out.

In an alternative embodiment of a plate utilizing an elongated slot to allow translational movement, the screws may be locked in place using any of the above-mentioned screws, methods, or devices. In this embodiment, the translational capabilities of the plate are used to allow the surgeon to make adjustments to the plate position, thereby allowing a surgeon to adjust load force and screw placement prior to locking the screws. For example, a surgeon may begin by inserting screws into the substantially circular, non-elongated openings on one distal end of the plate. Thereafter, the surgeon may place fasteners in the opposite distal end containing elongated slots. Once inserted, the surgeon may manual compress or decompress the vertebrae body or otherwise make adjustments to the positioning of the vertebrae bodies depending on graft size, fit, and location. The translational feature of the plate allows a surgeon to make these adjustments after insertion of the screws. Once the desired positioning has been reached, the surgeon may then lock the screws in place using the locking mechanisms described above.

Referring now to FIG. 20, another embodiment of a bone fixation plate 2000 is shown wherein the plate is configured to span multiple levels of vertebral bodies and allow translation of plate 2000 over multiple levels. Plate 2000 extends longitudinally along axis 2001 and extends laterally about axis 2003. As shown in FIG. 20, plate 2000 includes a pair of adjacent center holes 2002, 2004 located between pairs of adjacent elongated holes 2006, 2008 and 2010, 2012 positioned at opposite longitudinal ends of plate 2000. Holes 2002, 2006, 2010 and holes 2004, 2008, 2012 are aligned and spaced from the lateral center of plate 2000. In this embodiment, holes 2002, 2004 have a diameter sized to prevent lateral and longitudinal movement of a fastener extending therethrough relative to the plate. As shown, holes 2006, 2008 and 2010, 2012 have similar cross-sectional features to the elongated slots described above and are configured to prevent lateral movement and permit longitudinal translation of plate 2000 with respect to a fastener extending therethough as described previously. As described above, the slots 2006, 2008, 2010, and 2012 have a lateral width configured to accommodate the outer-most diameter (D) of the fastener head being used and prevent substantial lateral movement with respect thereto. In one embodiment, holes 2006, 2008 extend a longitudinal length 2009 and holes 2010, 2012 extend a longitudinal length 2013. In one embodiment length 2009 is substantially the same as length 2013, however in alternate embodiments holes 2006, 2008 can have different lengths than holes 2010, 2012. In one embodiment, length 2009 and 2013 is between about 1.2 and 1.6 (1.2 D-1.6 D) times the outer-most diameter of the fastener head being used. In another embodiment, the outer-most diameter of the fastener head (D) is about 5 mm and the length 2009 and 2013 is between about 6 mm and 8 mm. In another embodiment, the length 2009 and 2013 is about 7.0 mm. In yet another embodiment, the length 2009 and 2013 is configured to permit between about 0.5 mm to about 3 mm of translation of plate 2000 with respect to the fastener.

In operation, in one embodiment plate 2000 may be implanted and fastened to three adjacent vertebral bodies and the plate may translate or move to accommodate, for example, subsidence that may occur between the three adjacent vertebrae. Holes 2006, 2008 and 2010, 2012 are longitudinally spaced from center holes 2002, 2004 such that a first set of fasteners may be extended through holes 2006, 2008 to attach plate 2000 to a first vertebral body, a second set of fasteners may be extended through holes 2002, 2004 to attach plate 2000 to a second vertebral body, and a third set of fasteners may be extended through holes 2010, 2012 to attach plate 2000 to a third vertebral body. In operation, the first and third set of fasteners are preferably initially inserted through respective elongated holes such that the head of the fastener is positioned longitudinally at the end of the elongated hole closest to center holes 2002, 2004. If subsidence were to occur between the first and second vertebral bodies, the first set of fasteners may translate with respect to holes 2006, 2008 and plate 2000 may be allowed to translate a distance LT.sub.1, wherein LT.sub.1 equals 2009 minus the outer-most diameter (D) of the fastener head being used. Thus, in the embodiment where D is about 5 mm and length 2009 is between about 6 mm and 8 mm, plate 2000 may translate a distance LT.sub.1 between about 1 mm and 3 mm due to subsidence occurring between the first and second vertebral bodies. Similarly, if subsidence were to occur between the second and third vertebral bodies, the third set of fasteners may translate with respect to holes 2010, 2012 and plate 2000 may be allowed to translate a distance LT.sub.2, wherein LT.sub.2 equals 2013 minus the outer-most diameter (D) of the fastener head being used. Thus, in the embodiment where D is about 5 mm and length 2013 is between about 6 mm and 8 mm, plate 2000 may translate a distance LT.sub.2 between about 1 mm and 3 mm due to subsidence occurring between the second and third vertebral bodies. In the case where subsidence occurs between both the first and second vertebral bodies and between the second and third vertebral bodies, plate 2000 may translate a total distance LT.sub.Plate, wherein LT.sub.Plate equals LT.sub.1 plus LT.sub.2. Thus, in the aforementioned exemplary embodiment, plate 2000 may translate a distance LT.sub.plate up to a maximum of 6 mm when 2009 and 2013 equal 8 mm.

One skilled in the art will recognize that one advantage of the above-mentioned configuration, namely a plate design configured to attach to three separate vertebral bodies having adjacent pairs of translation permitting slots with an adjacent pair of non-translation permitting center holes positioned longitudinally therebetween, is that it allows for the same amount of total plate translation utilizing smaller or shorter elongated slots than other plate configurations. In this regard, a plate design utilizing shorter elongated slots allows for increased plate strength or, in the alternative, utilization of a thinner plate without compromising total plate strength.

For example, referring now to FIG. 21, one example of a plate 2100 with an alternative configuration of fastening holes is shown. An adjacent pair of non-translation permitting holes 2102, 2104 are provided at the a proximal end of the plate with two pairs of translation permitting slots 2106, 2108 and 2110, 2112 are arranged longitudinally along the plate. As shown in FIG. 21, the translation permitting slots 2110, 2112 located at the distal end of the plate are longer than middle slots 2106, 2108 in order to accommodate the same total plate translation. In comparison with the above example described with respect to plate 2000, in order to allow plate 2100 to accommodate subsidence of 3 mm between the first and second vertebral bodies and 3 mm between the second and third vertebral bodies, or a total plate translation of up to a maximum of 6 mm, the middle pair of adjacent slots 2106, 2108 would need to have a length of 8 mm to allow a 5 mm fastener head to translate 3 mm, and the outer pair of adjacent slots 2110, 2112 would need to have a length of 8 mm plus 3 mm, or 11 mm. Thus, the outer pair of slots 2110, 2112 would have to be longer (11 mm) than the longest pair of slots (8 mm) of the embodiment of the invention described above with respect to FIG. 20 in order to achieve the same maximum plate translation of 6 mm.

Referring to FIG. 22, another embodiment of a plate 2200 according to the present invention is shown. Plate 2200 is configured to span over four vertebral bodies and allow translation of plate 2200 over multiple levels. One skilled in the art will recognize that a similar hole and slot configuration to that used for plate 2000 is utilized. As shown in FIG. 22, plate 2200 includes a pair of adjacent non-translation permitting holes 2202, 2204 located between pairs of adjacent elongated holes 2206, 2208 and 2210, 2212 spaced on opposite longitudinal sides of holes 2202, 2204. An additional pair of adjacent elongated holes 2214, 2216 are spaced distally from holes 2210, 2212. In one embodiment, holes 2206, 2208 extend a longitudinal length 2209, holes 2210, 2212 extend a longitudinal length 2213, and holes 2214, 2216 extend a longitudinal length 2217. In one embodiment length 2209 is substantially the same as length 2213, and length 2217 is generally longer than lengths 2209, 2213. In alternate embodiments, holes 2206, 2208 can have different lengths than holes 2210, 2212. In one embodiment, length 2209 and 2213 is between about 1.2 and 1.6 (1.2 D-1.6 D) times the outer-most diameter of the fastener head being used. In another embodiment, the outer-most diameter of the fastener head (D) is about 5 mm and the length 2209 and 2213 is between about 6 mm and 8 mm. In another embodiment, the length 2209 and 2213 is about 7.0 mm. In yet another embodiment, the length 2209 and 2213 is configured to permit between about 0.5 mm to about 3 mm of translation of plate 2000 with respect to a fastener extending though holes 2206, 2208 and 2210, 2212, respectively. In one embodiment, length 2217 is between about 1.6 and 2.0 (1.6 D-2.0 D) times the outer-most diameter of the fastener head being used. In another embodiment, the outer-most diameter of the fastener head (D) is about 5 mm and the length 2217 is between about 8 mm and 11 mm. In another embodiment, the length 2217 is about 9.0 mm. In yet another embodiment, the length 2217 is configured to permit between about 0.5 mm to about 5.5 mm of translation of plate 2200 with respect to a fastener extending though holes 2214, 2216.

In operation, in one embodiment plate 2200 may be implanted and fastened to four adjacent vertebral bodies and the plate may translate or move to accommodate, for example, subsidence that may occur between the four adjacent vertebrae. A first set of fasteners may be extended through holes 2206, 2208 to attach plate 2200 to a first vertebral body, a second set of fasteners may be extended through holes 2202, 2204 to attach plate 2200 to a second vertebral body, a third set of fasteners may be extended through holes 2210, 2212 to attach plate 2200 to a third vertebral body, and a fourth set of fasteners may be extended through holes 2214, 2216 to attach plate 2200 to a fourth vertebral body. In operation, the first, third, and fourth set of fasteners are preferably initially inserted through respective elongated holes such that the head of the fastener is positioned longitudinally at the end of the elongated hole closest to holes 2202, 2204. If subsidence were to occur between the first and second vertebral bodies, the first set of fasteners may translate with respect to holes 2206, 2208 and plate 2200 may be allowed to translate a distance LT.sub.1, wherein LT.sub.1 equals 2209 minus the outer-most diameter (D) of the fastener head being used. Thus, in the embodiment where D is about 5 mm and length 2209 is 7 mm, plate 2200 may translate a distance LT.sub.1 of about 2 mm due to subsidence occurring between the first and second vertebral bodies. Similarly, if subsidence were to occur between the second and third vertebral bodies, the third set of fasteners may translate with respect to holes 2210, 2212 and plate 2200 may be allowed to translate a distance LT.sub.2, wherein LT.sub.2 equals 2213 minus the outer-most diameter (D) of the fastener head being used. Thus, in the embodiment where D is about 5 mm and length 2213 is 7 mm, plate 2200 may translate a distance LT.sub.2 of about 2 mm due to subsidence occurring between the second and third vertebral bodies. If subsidence were to occur between the third and fourth vertebral bodies, the fourth set of fasteners may translate with respect to holes 2214, 2216 and plate 2200 may be allowed to translate a distance LT.sub.3, wherein LT.sub.3 equals 2217 minus the outer-most diameter (D) of the fastener head being used and minus LT.sub.2. Thus, in the embodiment where D is about 5 mm and length 2217 is 9.0 mm, plate 2200 may translate a distance LT.sub.3 about 2 mm due to subsidence occurring between the third and fourth vertebral bodies. In the case where subsidence occurs between the first and second vertebral bodies, between the second and third vertebral bodies, and between the third and fourth vertebral bodies, plate 2200 may translate a total distance LT.sub.Plate, wherein LT.sub.Plate equals LT.sub.1 plus LT.sub.2 plus LT.sub.3. Thus, in the aforementioned exemplary embodiment, plate 2200 may translate a distance LT.sub.plate up to a maximum of 6 mm when 2209 and 2213 equal 7 mm, and 2217 equals 9 mm.

Referring to FIG. 23, another embodiment of a plate 2300 is shown that is similar to plate 2200 except an additional pair of adjacent elongated holes 2218, 2220 are provided that are longitudinally spaced proximally to holes 2206, 2208. Plate 2300 is configured to span over five vertebral bodies and allow translation of plate 2300 over multiple levels. In one embodiment, elongate holes 2218, 2220 have a length 2221 that is the same as length 2217. In another embodiment length 2221 is between about 1.6 and 2.0 (1.6 D-2.0 D) times the outer-most diameter of the fastener head being used. In another embodiment, the outer-most diameter of the fastener head (D) is about 5 mm and the length 2221 is between about 8 mm and 11 mm. In another embodiment, the length 2221 is about 9.0 mm. In yet another embodiment, the length 2221 is configured to permit between about 0.5 mm to about 5.5 mm of translation of plate 2300 with respect to a fastener extending though holes 2218, 2220.

Again, one advantageous feature of the above-mentioned configurations, namely a plate design configured to attach to four or five separate vertebral bodies having adjacent pairs of translation permitting slots with an adjacent pair of non-translation permitting holes positioned longitudinally therebetween, is that it allows for the same amount of total plate translation utilizing smaller or shorter elongated slots than other plate configurations. For example, in a configuration having non-translation permitting holes at one end of the plate, the additional elongated holes needed to allow the same total plate translation increase in length as the number of hole pairs increase.

Although the present invention has been described with respect to several embodiments, it will be understood by those skilled in the art that the present invention is capable of alternate embodiments within the spirit of the appended claims. For instance, while the embodiments described herein refer to a plate useful for the cervical region of the spine, skilled artisans would understand that the plate design described herein may also be used in other regions of the spine or even for fixation of other bones in other parts of the body. Thus, the invention is not limited only to treating the cervical spine. 

What is claimed is:
 1. A surgical system comprising: a plate having at least one elongated opening extending along a longitudinal axis, wherein the at least one elongated opening comprises a partially spherical curvature, wherein the plate comprises an interference region; at least one fastener comprising: a head with a partially spherical outer surface extending from a top of the head to a shaft portion, wherein the partially spherical outer surface has a diameter corresponding approximately to a minor axis of the least one elongated opening, wherein the head interferes with the plate at the interference region, wherein the head of the at least one fastener is capable of engaging with and passing through the interference region; a slit formed in the head and configured to permit outward expansion of the head; and a locking screw configured to be received in a receptacle formed in the head; and a drill guide receivable through the plate, wherein the drill guide is capable of receiving a drill for drilling a hole through bone, wherein the interference region is included in the partially spherical curvature and wherein the interference region includes multiple engagement areas and at least one relief area and wherein the at least one relief area is positioned between the multiple engagement areas.
 2. The surgical system of claim 1, wherein the drill guide is received in the at least one elongated opening formed in the plate.
 3. The surgical system of claim 2, wherein the drill guide comprises a threaded tip.
 4. The surgical system of claim 1, wherein the drill guide comprises a rotating barrel.
 5. The surgical system of claim 1, wherein the at least one elongated slot allows translational movement of the plate relative to the fastener.
 6. The surgical system of claim 1, wherein tangents from an outer most portion of the partially spherical curvature when viewed cross-sectionally intersect.
 7. The surgical system of claim 1, wherein the at least one fastener comprises at least one slit located on the fastener to permit outward expansion of the head.
 8. A surgical system comprising: a plate having a first elongated opening extending along a longitudinal axis and a second elongated opening extending along the longitudinal axis, wherein the first elongated opening comprises a partially spherical curvature, wherein the plate comprises an interference region; at least one fastener comprising: a head with a partially spherical outer surface extending from a top of the head to a shaft portion, wherein the partially spherical outer surface has a diameter corresponding approximately to a minor axis of the least one elongated opening, wherein the head interferes with the plate at the interference region, wherein the head of the at least one fastener is capable of engaging with and passing through the interference region; a slit formed in the head and configured to permit outward expansion of the head; and a locking screw configured to be received in a receptacle formed in the head; and a drill guide receivable through the plate, wherein the drill guide is capable of receiving a drill for drilling a hole through bone, wherein the interference region is included in the partially spherical curvature and wherein the interference region includes multiple engagement areas and at least one relief area and wherein the at least one relief area is positioned between the multiple engagement areas.
 9. The surgical system of claim 8, wherein the drill guide is received in the at least one elongated opening formed in the plate.
 10. The surgical system of claim 9, wherein the drill guide comprises a threaded tip.
 11. The surgical system of claim 8, wherein the drill guide comprises a rotating barrel.
 12. The surgical system of claim 8, wherein the at least one elongated slot allows translational movement of the plate relative to the fastener.
 13. The surgical system of claim 8, wherein tangents from an outer most portion of the partially spherical curvature when viewed cross-sectionally intersect.
 14. The surgical system of claim 8, wherein the at least one fastener comprises at least one slit located on the fastener to permit outward expansion of the head. 